JP2009133776A - Image pickup device and time correction method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent inconsistency of time information, and automatically make time correction, even when moving to an area having a different local time during imaging. <P>SOLUTION: A positioning information generation part 13 receives, for example, a GPS radio wave, and generates positioning information PT showing position information and a coordinated universal time. A control part 31 discriminates a time difference with the coordinated universal time from the position information shown by the positioning information PT, and calculates a local time on a position shown by the position information from the time difference, the coordinated universal time shown by the positioning information PT and summer time information. The control part 31 corrects a system time when a time difference between the system time shown by a timepiece part 22 and the local time exceeds a prescribed time. When performing recording operation of an imaged image, correction of the system time is waited until finish of the recording operation. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an imaging apparatus and a time correction method. Specifically, when the time difference between the system time indicated by the imaging device and the local time exceeds a predetermined time, if the recording operation of the captured image is being performed, the correction of the system time is waited until the recording operation is completed. Is.

  2. Description of the Related Art Conventionally, an imaging apparatus such as a video camera or a digital camera is provided with a clock function, and can record an imaging date and time and an imaging time together with a captured image. When traveling with an imaging device having such a clock function, when the travel destination has a time difference, the time of the imaging device (hereinafter referred to as “system time”) is set to the time of the travel destination. Operation is required. In addition, if the system time is not adjusted to the time of the travel destination, for example, the night time will be shown for images captured during the day, and the clock function cannot be used correctly. End up.

  Therefore, in the invention of Patent Document 1, a technique is proposed in which the local time is calculated by a position positioning technique, and the system time of the imaging apparatus is automatically corrected to the local time. Thus, if the system time of the imaging apparatus is automatically corrected to the local time, the correct time can be recorded together with the captured image without the user performing a time adjustment operation.

JP 2000-75070 A

  By the way, when moving between countries or regions having different local times, if the system time of the imaging apparatus is automatically corrected to the local time, a time advance or delay occurs during the imaging operation. For this reason, when a moving image is recorded as a captured image, a mismatch occurs in the time recorded in the moving image stream. In addition, there may be a mismatch between the time recorded in the moving image stream at the start of imaging and the time when the moving image stream is registered in the file system as a moving image file. For example, if the system time that changes the time is changed during video recording, the time of the video file registered in the system file after the recording operation ends indicates the time before the start of imaging and is inconsistent. Will occur.

  Therefore, the present invention provides an imaging apparatus and a time correction method that can automatically correct the correct time while preventing time information inconsistencies.

  The concept of the present invention is that when moving in a region where there is a time difference in local time while recording a captured image, even if there is a time difference between the system time of the imaging device and the local time due to the movement, the system continues until the recording of the captured image It is to wait for correction of the time.

  An imaging apparatus according to the present invention, in an imaging apparatus that records a captured image and time information indicating an imaging time, acquires position information and coordinated universal time, and generates a positioning information indicating an acquisition result, and a positioning information generation unit; A time difference determination unit that determines a time difference from Coordinated Universal Time from the position information indicated by the positioning information, and a position indicated by the position information indicated by the positioning information from a Coordinated Universal Time indicated by the positioning information and the time difference. A local time calculation unit for calculating a local time, and when the time difference between the system time indicated by the imaging device and the local time exceeds a predetermined time, the system time is corrected, and the recording operation of the captured image is performed. If it is not, a time adjustment unit for waiting for the correction of the system time until the end of the recording operation is provided.

  The time correction method according to the present invention is a time correction method for an imaging apparatus that records an image signal of a captured image and time information indicating the imaging time. The positioning information is generated from a positioning information generating step for generating information, a time difference determining step for determining a time difference with Coordinated Universal Time from the position information indicated by the positioning information, and a coordinated time and the time difference indicated by the positioning information. A local time calculating step of calculating a local time of the position indicated by the position information indicating, and correcting the system time when a time difference between the system time indicated by the imaging device and the local time exceeds a predetermined time. And when the captured image recording operation is being performed, a time adjustment step is provided in which the correction of the system time is waited until the end of the recording operation.

  In the present invention, position information and coordinated universal time are acquired by receiving a radio signal and receiving, for example, GPS radio waves. Further, the time difference from the coordinated universal time is determined from the position information, and the local time of the position indicated by the position information is calculated from the time difference from the coordinated universal time and the daylight saving time information. Here, the system time is corrected when the time difference between the system time indicated by the imaging apparatus and the local time exceeds a predetermined time. When a captured image recording operation is performed, the correction of the system time is awaited until the end of the recording operation, and then a display to that effect is displayed when the system time is corrected.

  According to the present invention, even when moving to a region where the local time is different while recording a captured image, the system time is not corrected during the recording operation of the captured image, and the correct time is reached after the recording operation is completed. Will be corrected. For this reason, even if the user is not aware of whether or not the local time has moved to a different region or whether or not the captured image is being recorded, the time of the recorded video file may be inconsistent. The system time of the image pickup apparatus can be automatically corrected. Further, since the system time is corrected based on the coordinated universal time, the position information, and the daylight saving time information, the system time can be corrected to the correct time.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows the configuration of an imaging apparatus according to the present invention.

  The optical system unit 11 of the image pickup apparatus 10 is configured by a lens, a zoom mechanism, and the like, and forms an optical image on the image pickup surface of the image pickup element 121 disposed behind the optical axis of the lens.

  The imaging device 121 of the imaging unit 12 performs photoelectric conversion, generates an analog image signal corresponding to the optical image, and supplies the analog image signal to the analog signal processing unit 122. The analog signal processing unit 122 performs analog image signal processing such as noise removal and gain adjustment on the analog image signal supplied from the image sensor 121. Further, the analog signal processing unit 122 is provided with an A / D converter, converts the analog image signal subjected to the analog signal processing into a digital image signal, and supplies the digital image signal to the image processing unit 123.

  The image processing unit 123 performs digital image signal processing such as color adjustment and image quality adjustment using the digital image signal supplied from the analog signal processing unit 122. In addition, compression processing of an image signal subjected to digital image signal processing, expansion processing of an image signal subjected to compression processing, and the like are performed. As a compression method, in the case of moving image recording, for example, an MPEG (Moving Picture Expert Group) method or the like is used. In the case of still image recording, an irreversible compression method such as a JPEG (Joint Photographic Experts Group) method is used. The image processing unit 123 may generate a RAW lossless compressed signal or an uncompressed signal, or may generate a TIFF (Tagged Image File Format) uncompressed signal. Hereinafter, an uncompressed or compressed image signal is simply referred to as an image signal DG.

  The positioning information generation unit 13 acquires position information and coordinated universal time, and generates positioning information PT indicating the acquisition result. The positioning information generation unit 13 is configured using, for example, a GPS (Global Positioning System) device. The GPS device includes an antenna unit that receives GPS radio waves, a signal conversion unit for received GPS radio waves, a position information calculation unit, a coordinated universal time information generation unit, and the like. It generates positioning information PT in the NMEA (National Marine Electronics Association) -0183 format.

  FIG. 2 shows a part of the positioning information PT in the NMEA-0183 format generated by the positioning information generating unit 13, for example, a GGA data sentence. The data is shown as an example. “Message ID” indicates a GGA data sentence. The leading “$” is the beginning of a character string, and “GP” is an identifier indicating GPS positioning information. In “UTC Position”, the positioning time is indicated in Coordinated Universal Time. “Latitude” indicates latitude, and “N / S Indicator” indicates whether latitude is north latitude or south latitude. “Longitude” indicates longitude, and “E / W Indicator” indicates whether longitude is east longitude or west longitude. “Position fix indicator” indicates GPS quality, and “Satellites used” indicates the number of received satellites. Further, the positioning information PT includes not only the GGA data sentence but also the ZDA data sentence or the RMC data sentence, so that the information on the year, month and day of the coordinated universal time can be obtained.

  Further, the positioning information generating unit 13 may generate positioning information PT by receiving not only GPS radio waves but also other radio signals. For example, the positioning information generation unit 13 is configured using a communication device to generate position information by measuring the arrival time difference of radio waves from a mobile phone base station, or based on the strength of radio waves from a PHS base station The position information is generated by estimating the distance. It is also possible to receive radio waves from a plurality of terrestrial digital television broadcast stations and generate position information based on the arrival time difference of the radio waves, or generate position information by communication with a wireless LAN access point. It is also possible to acquire Coordinated Universal Time by accessing a time server via a network.

  The image recording / reproducing unit 14 is configured using a recording medium such as a nonvolatile memory, an optical disk, a hard disk device, or the like. The image recording / reproducing unit 14 records an image signal DG of a captured image, for example, a still image or moving image signal DG, together with time information such as an imaging time. Also, the image signal DG recorded on the recording medium is reproduced. If the image signal DG and the like are recorded in a file, the recorded image signal DG can be easily managed.

  The display unit 15 is configured using a liquid crystal display element or the like, and displays a finder image based on the image signal output from the imaging unit 12. The display unit 15 also displays captured images based on image signals stored in the image recording / reproducing unit 14 and various menu displays.

  The memory unit 21 stores a program for operating the imaging device 10 and table information used for calculating a time difference. In addition, when the use of the imaging device 10 is assumed in a country where the daylight saving time system is adopted, information (hereinafter referred to as “summer time information”) that can identify a period in which the time is advanced is provided in the table information.

  The clock unit 22 generates time information indicating the system time of the imaging apparatus 10, and supplies the generated time information to the control unit 31. The system time of the clock unit 22 can be changed by the control unit 31.

  A user interface unit 32 is connected to the control unit 31. The user interface unit 32 includes a shutter button and an operation dial for switching the imaging mode. The user interface unit 32 generates an operation signal SS corresponding to a user operation and supplies the operation signal SS to the control unit 31.

  The control unit 31 is connected to each unit via the bus 35. The control unit 31 reads out and executes a program stored in the memory unit 21 to start the operation of the imaging device 10. In addition, the control unit 31 generates the control signal CT according to the operation signal SS supplied from the user interface unit 32 and supplies the control signal CT to each unit, thereby operating the imaging device 10 according to the user operation.

  Further, the control unit 31 determines a time difference from the coordinated universal time from the position information indicated by the positioning information PT generated by the positioning information generating unit 13, and the coordinated universal time indicated by the time difference and the positioning information PT. From this, the local time of the position indicated by the position information is calculated. When the use of the imaging device 10 is assumed in a country where the daylight saving time system is adopted, the local time is calculated using daylight saving time information. In addition, the control unit 31 corrects the system time according to the system time of the clock unit 22, the calculated local time, and the operation state of the imaging device 10.

  Next, a description will be given of a system time correction operation in the imaging apparatus. FIG. 3 is a flowchart of a correction determination operation for determining whether or not to correct the system time. FIG. 4 is a flowchart showing the correction processing operation when it is determined that the system time needs to be corrected by the determination operation of FIG.

  Here, if the time interval for determining whether or not to correct the system time is long, the system time cannot be quickly changed when moving to an area where the time difference with respect to the coordinated universal time is different. Therefore, it is desirable that the time interval for determining whether or not to correct the system time is short. On the other hand, the system time correction operation may be performed only when it is determined that the system time needs to be corrected. That is, it is desirable that the operation for determining whether or not to correct the system time and the system time adjustment operation be asynchronous processing. Therefore, in the operation of FIG. 3, when it is determined that the system time needs to be corrected, a system time correction request is made to another process or thread operation, and the correction process operation shown in FIG. Assumed to be performed.

  In step ST1 of FIG. 3, the control unit 31 acquires the positioning information PT generated by the positioning information generation unit 13, and proceeds to step ST2. As described above, since the positioning information PT generated by the positioning information generating unit 13 includes information indicating latitude, longitude, and coordinated universal time, the control unit 31 acquires the positioning information PT. The current position and the current coordinated universal time can be determined.

  In step ST2, the control unit 31 determines the time difference. Further, when the use of the imaging device 10 is assumed in a country where the daylight saving time system is adopted, the control unit 31 acquires daylight saving time information. The control unit 31 calculates a time difference from the coordinated universal time with respect to the current position from the latitude and longitude indicated by the positioning information. For example, table information is generated and stored in the memory unit 21 so that the time difference between the current position and the coordinated universal time can be obtained when latitude and longitude are specified. Further, the control unit 31 acquires summer time information from the latitude and longitude of the current position. For example, table information is generated and stored in the memory unit 21 so that summer time information for the current position can be obtained when latitude and longitude are specified. If the table information is generated in this way, it is easy to determine the time difference and obtain the summer time information.

  FIG. 5 illustrates table information. In this table information, regions are divided into meshes in units of latitude and longitude and seconds, and time difference and daylight saving time information are shown for each divided region.

  For example, in a range from 20 degrees east longitude to 25 degrees east longitude (E02000.0000 to E02500.0000), a range from 50 degrees north latitude to 40 degrees north latitude indicates the position of Europe. In this area, the daylight saving time information indicates that the time is advanced by 1 hour from 1 am to 3 am on the last Sunday in March to 1 am on the last Sunday in October (coordinated universal time standard). The range from 30 degrees north latitude to 25 degrees north latitude indicates the position of Africa. In this region, the summer time information indicates that summer time is not being performed.

  Note that the table information in FIG. 5 shows the time difference and the daylight saving time information by dividing the region into a mesh shape, but the region division is not limited to the mesh shape. For example, an area where the time difference and the daylight saving time information are the same may be held as polygon data of latitude and longitude, and the time difference and daylight saving time information of the area including the latitude and longitude of the current position may be read.

  In step ST3, the control unit 31 calculates the local time. The controller 31 calculates the time by adding the time difference to the coordinated universal time. Furthermore, when it is the daylight saving time implementation period, the calculated time is corrected, and the corrected time is set as the local time which is the time of the current position, and the process proceeds to step ST4. If it is not the daylight saving time implementation period or the daylight saving time system is not adopted, the process proceeds to step ST4 with the time obtained by adding the time difference as the coordinated universal time as the local time.

  In step ST4, the control unit 31 determines whether or not the time difference TD between the system time and the local time exceeds a predetermined time Tth. The control unit 31 calculates a time difference TD between the local time calculated in step ST3 and the system time indicated by the clock unit 22. If the time difference TD does not exceed the predetermined time Tth, the process returns to step ST1. If the time difference exceeds the predetermined time, the process proceeds to step ST5.

  In step ST5, the control unit 31 makes a system time correction request and returns to step ST1.

In step ST11 of FIG. 4, the control unit 31 determines whether or not a system time adjustment request has been made. Here, when the system time adjustment request is not made, the process returns to step ST11, and when the system time adjustment request is made, the process goes to step ST12.
In step ST <b> 12, the control unit 31 determines whether the captured image is being recorded. When the operation of recording the image signal DG obtained by the imaging unit 12 on the recording medium is performed by the image recording / reproducing unit 14, the control unit 31 proceeds to step ST13. When the captured image recording operation is completed or when the captured image recording operation is not performed, the process proceeds to step ST14.

  In step ST13, the control unit 31 waits for a predetermined time and returns to step ST12.

  In step ST14, the control unit 31 corrects the system time. That is, the control unit 31 corrects the system time of the clock unit 22 so that the time difference between the system time calculated in step ST4 and the local time becomes “0”, and returns to step ST11. Here, when the system time is corrected, a display to that effect is displayed on the display unit 15. By displaying that the system time has been corrected, the user can confirm that the system time has been automatically corrected to the local time of the current position.

  As described above, if the system time is corrected, the system time is not corrected during the recording operation even if the local time is moved between countries or regions during recording of the captured image. Therefore, there is no time mismatch when recording a captured image as a moving image. In addition, since the system time is corrected after the recording operation is completed, the user confirms whether or not the user has moved to a country or region with a different local time, that is, whether the time zone has changed, and performs the system time correction operation each time Even without this, the system time of the imaging apparatus can be automatically corrected to the time of the current position.

  The correction processing operation shown in FIG. 4 automatically corrects the system time when a system time correction request is made, but automatically corrects the system time when the user obtains permission. It is good. Specifically, when it is determined in step ST11 that the system time adjustment request has been made, it is determined whether or not the user's permission has been obtained. When it is determined that the user's permission has been obtained, the steps after step ST12 are performed. Processing shall be performed.

  In this way, by automatically correcting the system time only when the user permits, for example, when the period of travel to a region where the local time is different is short and the system time does not need to be changed, or the user desires When the time is recorded, it is possible to prevent the system time from being automatically changed.

It is a figure which shows the structure of an imaging device. It is a figure which shows a part of positioning information. It is a flowchart which shows correction | amendment judgment operation | movement. It is a flowchart which shows correction process operation | movement. It is a figure which shows table information.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Imaging device, 11 ... Optical system unit, 12 ... Imaging part, 13 ... Positioning information generation part, 14 ... Image recording / reproducing part, 15 ... Display part, 21 ... Memory unit 22 ... Clock unit 31 ... Control unit 32 ... User interface unit 35 ... Bus 121 ... Image sensor 122 ... Analog signal processing unit 123 ..Image processing unit

Claims (8)

In an imaging apparatus that records time information indicating a captured image and an imaging time,
A positioning information generating unit that acquires position information and coordinated universal time, and generates positioning information indicating an acquisition result;
A time difference determination unit for determining a time difference from Coordinated Universal Time from the position information indicated by the positioning information;
A local time calculating unit that calculates the local time of the position indicated by the position information indicated by the positioning information from the coordinated universal time indicated by the positioning information and the time difference;
When the time difference between the system time indicated by the imaging device and the local time exceeds a predetermined time, the system time is corrected, and if the recording operation of the captured image is performed, the system time An image pickup apparatus comprising a time correction unit that waits for correction until the end of the recording operation. A daylight saving time information storage unit for storing daylight saving time information indicating a period for advancing the time is provided.
The imaging apparatus according to claim 1, wherein the local time calculation unit calculates the local time from the coordinated universal time, the time difference, and the daylight saving time information. The imaging apparatus according to claim 2, wherein the position information acquisition unit and the coordinated universal time acquisition unit acquire the position information and the coordinated universal time by receiving a radio signal. The imaging apparatus according to claim 3, wherein the position information acquisition unit and the coordinated universal time acquisition unit are GPS (Global Positioning System) devices. The imaging apparatus according to claim 3, wherein the position information acquisition unit and the coordinated universal time acquisition unit are communication devices that perform wireless communication via a network. The imaging device includes a display unit,
The imaging apparatus according to claim 3, wherein the time correction unit displays the fact on the screen of the display unit after correcting the system time. The imaging apparatus includes a user interface unit that generates an operation signal according to a user operation,
Before correcting the system time, the time correction unit displays a message to that effect on the screen of the display unit, and corrects the system time when the operation signal indicates a correction instruction for the system time. The imaging apparatus according to claim 6. In the time correction method of the imaging device that records the image signal of the captured image and the time information indicating the imaging time,
A positioning information generation process for acquiring location information and coordinated universal time and generating positioning information indicating the acquisition result;
A time difference determining step of determining a time difference from Coordinated Universal Time from the position information indicated by the positioning information;
A local time calculating step of calculating a local time of the position indicated by the position information indicated by the positioning information from the coordinated universal time indicated by the positioning information and the time difference;
When the time difference between the system time indicated by the imaging device and the local time exceeds a predetermined time, the system time is corrected, and when the recording operation of the captured image is performed, the system time A time correction method comprising a time correction step of waiting for correction until the end of the recording operation.

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